KR20080056200A - Catheter type iontophoresis apparatus - Google Patents

Abstract

Catheter type iontophoresis apparatus (10) comprising endoscope unit (20) and, disposed at a distal end of flexible cable (18) thereof, small working-side electrode structure (12) and non-working-side electrode structure (14). Pin-point infiltration of drug solution can be accomplished by closely adhering first ion exchange membrane (44) and fourth ion exchange membrane (54) provided at the distal end thereof to, for example, a cancer site of the digestive organ and carrying out iontophoresis. The working-side electrode structure (12) and non-working-side electrode structure (14) are mounted at a distal end of rodlike member (16), and the rodlike member (16) is freely attachable to or detachable from the distal end of the flexible cable (18), being replaceable integrally.

Description

Catheter type iontophoresis device {CATHETER TYPE IONTOPHORESIS APPARATUS}

The present invention relates to an iontophoresis device for administering a drug ion to a living body.

The iontophoresis device as described above penetrates the chemical liquid into the skin and mucous membranes, and conventionally targets skin or mucous membranes having a relatively large area of about 20 mm in diameter even if small.

On the other hand, a part of the area targeted for the surgical operation under the endoscope, the intranasal mucosa, the intraoral mucosa, the esophagus, the stomach, the small intestine, the large intestine, the anus, and the lesion at the time of laparoscopy in the treatment of lung cancer, open surgery Direct injection of a drug into a part (pin point) exposed in the back may increase the therapeutic effect.

In such a case, it is preferable to infiltrate the drug by iontophoresis rather than to inject because it is non-invasive.

In addition, when the PDT (Photodynamic Therapy) is administered, the anti-cancer effect is expected by irradiating light after administering the photosensitizer. Since the photosensitizer spreads in the body, the patient is prevented from being irradiated with sunlight. In addition, it may spread to areas other than the affected part and cause side effects. Therefore, during PDT, it is hoped that the photosensitizer will be administered only to the affected area.

The present invention provides a suitable iontophoresis device for use in infiltrating a chemical solution only to a part of a living body, such as a cancerous site, in the case of treatment or treatment using an endoscope or a laparoscope.

The following problems can be solved by various examples below.

(1) A direct current power source connected to the working side electrode structure and the non-acting electrode structure used for administering the ionic agent by iontophoresis, and the working side electrode structure and the non-acting electrode structure with different polarity. An iontophoresis device, comprising: a rod-shaped member for supporting the acting side electrode structure and the non-acting side electrode structure, and an endoscope apparatus for freely attaching and detaching the rod-shaped member. The side electrode structure and the non-action side electrode structure are disposed at the tip of the rod-shaped member, and a gap of a constant distance is formed between them, and the rod-shaped member is flexible in the endoscope device. It is characterized in that the attachment and detachment of the flexible cable supported to be bent by the tube is freely supported. The catheter-type iontophoresis apparatus.

(2) The ionic agent is a light sensitizing substance that absorbs and operates light, and the endoscope device has an irradiation optical system that irradiates light from near the tip of the working side electrode structure by the flexible tube. The catheter type iontophoresis device as described in said (1) characterized by the above-mentioned.

(3) The endoscope apparatus has an endoscope optical system including an optical fiber for irradiation light for irradiating the inside of the living body and an optical fiber for reflection light for guiding the reflected light to the outside, wherein the irradiation optical system is the optical fiber for irradiation light. The catheter type iontophoresis device as described in said (2).

(4) In the flexible cable, wiring from the DC power supply is housed, and has a power supply side working electrode terminal and a power supply side non-operating electrode terminal connected to different polarities of the DC power supply through the wiring, and the rod-shaped member includes: And a working electrode side contact and a non-acting electrode side contact, which are connected or separated at the time of attaching and detaching, to the power supply side working electrode terminal and the power supply side non-operating electrode terminal at the base end of the detachable side to the flexible cable. The working electrode side contact and the non-acting electrode side contact are connected to the working side electrode and the non-acting side electrode in the working side electrode structure and the non-acting side electrode structure, wherein (1) to (3) above. The catheter type iontophoresis device in any one of Claims.

(5) The endoscope device is provided with a control device, which is arranged in a power supply circuit between the power supply side electrode terminal and the power supply side non-action side electrode terminal and the DC power supply. The catheter type iontophoresis device as described in said (4) characterized by adjusting an electric current value at least among the electric current time which is an electric current value and administration time of a display.

(6) The catheterized iontophore according to any one of (1) to (5), wherein the acting electrode structure and the non-acting electrode structure are arranged so that their respective central axes are parallel. Sheath device.

(7) The catheter type according to any one of (1) to (5), wherein the acting side electrode structure and the non-acting side electrode structure are arranged so that each central axis extends and expands in the tip direction. Iontophoresis device.

(8) The catheter type ion according to any one of (1) to (5), wherein the working side electrode structure and the non-working side electrode structure are arranged so that their respective central axes cross in the tip direction. Toporesis device.

(9) The said working side electrode structure is arrange | positioned at the front side of this working side electrode connected to the polarity of the same kind as the charging ion of the said ionic chemical agent in the said DC power supply, and contains electrolyte solution A second ion exchange membrane disposed on the electrolyte holding portion, on the front surface of the electrolyte holding portion, and selecting an ion opposite to the charged ion of the ionic agent; and disposed on the front surface of the second ion exchange membrane. And a first ion exchange membrane which is disposed on the front side of the chemical liquid holding portion and the ion exchange membrane which selects ions of the same kind as the ions of the ionic drug. The non-acting side electrode connected to the polarity opposite to the charged ion of the ionic drug in the DC power supply, and disposed on the front surface of the non-acting side electrode, for holding a second electrolyte solution. A third ion exchange membrane disposed on the front surface of the second electrolyte holding portion, the front side of the second electrolyte holding portion, and selecting a ions of the same type as the ions of the ionic agent; And a fourth ion exchange membrane which is disposed on the front surface of the third electrolyte holding portion for holding the electrolyte and the ion exchange membrane for selecting ions opposite to the charged ions of the ionic drug. The catheter type iontophoresis device as described in any one of said (1)-(8).

BRIEF DESCRIPTION OF THE DRAWINGS The top view which shows the iontophoresis apparatus in embodiment of this invention.

Fig. 2 is an enlarged cross-sectional view showing main parts of the acting electrode structure and the non-acting electrode structure.

3 is a plan view showing another arrangement example of the acting side electrode structure and the non-acting side electrode structure.

4 is a plan view showing another arrangement example of the acting side electrode structure and the non-acting side electrode structure.

EMBODIMENT OF THE INVENTION Hereinafter, the best form for implementing this invention is demonstrated in detail with reference to drawings.

As shown in FIG. 1, FIG. 2, the catheter-type iontophoresis apparatus 10 in this best embodiment is the action side electrode structure 12 and non-action side used for administering an ionic agent. To the electrode structure 14, the rod-shaped member 16 supporting them integrally, and the direct current power source 30 connected to the working side electrode structure 12 and the non-acting side electrode structure 14 with different polarities. Consists of.

The working side electrode structure 12 and the non-working side electrode structure 14 are provided at the tip of the rod-shaped member 16, and the rod-shaped member 16 is at the tip of the flexible cable 18. The attachment and detachment are freely supported, whereby the acting side electrode structure 12 and the non acting side electrode structure 14 can be exchanged integrally with the rod-shaped member 16.

The flexible cable 18 is supported so as to be bent freely by the flexible tube 22 of the endoscope apparatus 20, and the rod-shaped member 16 is attached to the tip which protrudes from the flexible tube 22. The mask is installed freely.

The endoscope device 20 has an endoscope optical system including an optical fiber 24 for irradiation light and an optical fiber 26 for reflection light, passing through the flexible tube 22. The irradiated light optical fiber 24 emits irradiated light from the tip, and the reflected optical fiber 26 captures the reflected light generated from the affected part in the living body by the irradiated light emitted from the irradiated optical fiber 24 to the outside. It is intended to induce. White light enters the optical fiber 24 for irradiation light from a laser light source 58 described later.

The working electrode structure 12 and the non-working electrode structure 14 are connected to different polarities of the DC power supply 30 by a power supply circuit (not shown).

At the end of the rod-shaped member 16 on the flexible cable 18 side, the non-acting side connected to the acting side electrode terminal 32 connected to the acting side electrode structure 12 and the non-acting side electrode structure 14. The electrode terminal 34 is provided.

These acting side electrode terminals 32 and non-acting side electrode terminals 34 have a power supply side pre-acting electrode terminal on the flexible cable 18 side when the rod-shaped member 16 is mounted on the flexible cable 18. 33) and the non-operating electrode terminal 35 on the power supply side, respectively.

The power supply side working electrode terminal 33 and the power supply side inactive electrode terminal 35 are connected to the DC power supply 30 provided outside the endoscope apparatus 20 by the power supply circuit 28.

The rod-shaped member 16 is a cylindrical member having the same diameter as the flexible cable 18. The rod-shaped member 16 is screwed by the male threaded portion 16A to the female threaded portion 18A at the distal end of the flexible cable 18. It is also installed so that it can be removed by rotating the screw in the opposite direction.

The acting side electrode structure 12 and the non-acting side electrode structure 14 are arranged so that their respective center axes are parallel as shown in an enlarged view in FIG. 2. The working side electrode structure 12 has the working side electrode 36, the electrolyte holding part 38, the second ion exchange membrane 40, and the chemical holding part 42 from the rod-shaped member 16 side. ) And the first ion exchange membrane 44 are laminated in this order, and are formed in a disc shape having a diameter of about 2 to 6 mm.

The working side electrode 36 may be made of a conductive paint coated on one surface of the base sheet 13, for example, containing a non-metal conductive filler such as carbon paste. The working side electrode 36 may be formed of a copper plate or a metal thin film. However, since the eluted metal component transfers to a living body at the time of drug administration, the non-metallic property is preferable.

The electrolyte holding portion 38 is composed of, for example, an electrolytic coating applied to the working side electrode 36. This electrolyte paint is a paint containing an electrolyte, and is an electrolyte which is more easily oxidized or reduced than the electrolytic reaction of water (oxidation at the plus electrode and reduction at the negative electrode), for example, ascorbic acid (vitamin C) or ascorbic acid. It is particularly preferable to use pharmaceutical agents such as sodium vinate, organic acids such as lactic acid, oxalic acid, malic acid, succinic acid and fumaric acid and / or salts thereof, whereby the generation of oxygen gas or hydrogen gas can be suppressed. In addition, when dissolving in a solvent, it is also possible to suppress the fluctuation of pH during energization by blending a plurality of kinds of electrolytes combined with a buffer electrolyte.

Hydrophilic polymers, such as polyvinyl alcohol, polyacrylic acid, polyacrylamide, and polyethylene glycol, are mix | blended with electrolyte paint in order to improve the coating property and film forming property as paint, and water and ethanol for adjusting the viscosity of electrolyte paint And solvents such as propanol are blended in an appropriate amount. In addition, suitable additional ingredients such as thickeners, thixotropic agents, antifoams, pigments, flavorings, and coloring agents may also be blended.

The second ion exchange membrane 40 is formed by applying a second ion exchange paint to the electrolyte holding portion 38.

The second ion exchange paint is a paint containing an ion exchange resin having an ion exchanger introduced with a counter ion as a counter ion of the drug ion in the chemical solution holding portion 42 described later. An anion exchange resin is blended when a drug whose active ingredient in section 42 dissociates to a positive drug ion is used. On the contrary, when a drug whose drug is dissociated to a negative drug ion is used, a cation exchange resin is used. Compounded.

The chemical liquid holding part 42 is made of a chemical coating applied to the second ion exchange membrane 40, and is dissolved in a solvent such as water to dissolve the active ingredient in positive or negative ions (drug ion). It is a coating material containing a chemical | medical agent (including the precursor of a pharmaceutical agent), As an agent whose drug substance dissociates to positive ion, an anesthetic drug lidocaine hydrochloride, morphine hydrochloride, etc. can be illustrated, and a drug substance dissociates to negative ion As a pharmaceutical agent, ascorbic acid etc. which are a vitamin agent can be illustrated.

The first ion exchange membrane 44 is formed of a first ion exchange coating applied to the chemical liquid holding portion 42. The first ion exchange paint is a paint containing an ion exchange resin into which an ion exchange group having the same conductivity type as the ion of the drug ion in the chemical holding portion 42 as a counter ion is introduced. When a medicament is used in which a component dissociates into positive or negative drug ions, an anion exchange resin or a cation exchange resin is blended.

Examples of the cation exchange resin include a sulfonic acid group, a carboxylic group, and a phosphate group in a polymer having a three-dimensional network structure such as a hydrocarbon resin such as polystyrene resin or acrylic acid resin, or a fluorine resin having a perfluorocarbon skeleton. The ion exchange resin into which the cation exchange group (exchange ion whose counterion is cation), such as a phonic acid group, can be used without limitation.

Moreover, as said anion exchange resin, the polymer which has a three-dimensional network structure similar to the said cation exchange resin is a 1-tertiary amino group, a quaternary ammonium group, a pyridyl group, an imidazole group, a quaternary pyridinium group, and a quaternary imide. The ion exchange resin into which an anion exchange group (exchange ion which the counter ion is an anion), such as a dazolium group, can be used without limitation.

The non-action side electrode structure 14 includes a non-action side electrode 46 formed on one side of the non-action side base sheet 15, a second electrolyte holding portion 48, and a third ion exchange membrane 50. ), The third electrolyte holding portion 52, and the fourth ion exchange membrane 54 are laminated in this order, and have a disc shape in the same manner as the working side electrode structure 12.

The non-acting side electrode 46 has the same configuration as the acting side electrode 36 in the acting side electrode structure 12, and the second electrolyte holding portion 48 and the third electrolyte holding portion ( The constitution and components of 52) are also the same as those of the electrolyte holding portion 38 described above.

In addition, the third ion exchange membrane 50 is formed of an ion exchange paint coated on the second electrolyte holding portion 48. This ion exchange coating is the same as the first ion exchange coating forming the first ion exchange membrane 44 and functions as the same ion exchange membrane as the first ion exchange membrane 44.

The fourth ion exchange membrane 54 is formed of the same second ion exchange paint applied on the third electrolyte solution holding portion 52 as described above. The fourth ion exchange membrane 54 functions as the same ion exchange membrane as the second ion exchange membrane 40.

On the other side of the base sheet 13, a working side electrode terminal plate 32A is provided, and this working side electrode terminal plate 32A is provided with respect to the working side electrode 36 of the working side electrode structure 12. The conductive sheet is electrically connected through the through hole formed in the base sheet 13 and is connected to the working electrode terminal 32.

Similarly, 34 A of non-acting side electrode terminal boards are provided in the other surface of the said non-acting side base sheet 15, and this non-acting side electrode terminal board 34A of the non-acting side electrode structure 14 is carried out. The non-action side electrode 46 is connected to the non-action side electrode terminal 34 while being conducted through a through hole formed in the non-action side base sheet 15.

The working side electrode structure 12 and the non-working electrode structure 14 are both exposed to the living body by exposing the first exchange membrane 44 and the fourth ion exchange membrane 54 at their ends, respectively. It is supposed to be.

The DC power supply 30 is formed of, for example, an AC / DC converter, and the power supply circuit between the DC power supply 30 and the power supply side working electrode terminal 33 and the power supply side inactive electrode terminal 35 ( In 28), a control device 56 for adjusting at least the current value is provided among the current value at the time of energization and the current supply time at the administration time, and the current value and the administration time can be adjusted within a certain range.

Here, the first ion exchange membrane 44 and the fourth ion exchange membrane 54 at the tips of each of the working side electrode structure 12 and the non-acting electrode structure 14 do not directly flow current therebetween. In order to avoid that, a constant gap S is formed. This gap S has a size substantially equal to the diameter of the first ion exchange membrane 44 and the fourth ion exchange membrane 54.

At the time of treatment, white light is irradiated from the irradiated optical fiber 24, the reflected light is guided to the outside by the reflected optical fiber 26, and the affected part is identified while observing this, and the working side electrode structure ( 12) can be pushed. No illumination during iontophoresis.

In addition, although the center axis line of the acting side electrode structure 12 and the non acting side electrode structure 14 is provided in parallel in the said embodiment, this invention is not limited to this, For example, FIG. As shown in 3, the center axis line of the acting side electrode structure 12 and the non-acting side electrode structure 14 may be arrange | positioned so that it may cross | intersect at 60 degrees toward a tip direction, and, as shown in FIG. 4, a center axis line You may comprise so that this may expand.

In these embodiments, since the acting side electrode structure 12 and the non-acting side electrode structure 14 are arrange | positioned with the clearance gap S at the front-end | tip of the flexible cable 18 in the endoscope apparatus 20, For example, in the case of infiltrating the chemical liquid into the cancerous part of the fire extinguisher, the doctor grasps the endoscope device 20 and the first ion exchange membrane at the tip of the working side electrode structure 12 at the tip of the flexible cable 18. If the 44 is in close contact with the arm, and the fourth ion exchange membrane 54 at the tip of the non-action side electrode structure 14 is also in close contact with the mucous membrane in the vicinity, and energized, the desired chemical liquid can be easily moved to the desired position. It can easily penetrate to the pinpoint.

In addition, since the working side electrode structure 12 and the non-working side electrode structure 14 together with the rod-shaped member 16 can be removed from the flexible cable 18, the chemical liquid can be easily exchanged.

The catheterized iontophoresis device 10 is, for example, the treatment in the body by PDT, which is an anticancer therapy that absorbs light by applying a light sensitizer to cancer cells and then absorbs the light, for example, a superficial type (表 在 型) Esophageal cancer, superficial gastric cancer, cervical cancer can be used to treat. In addition to PDT, it can be used for the treatment of the body, for example, the treatment of gastric ulcer, colitis, and the like.

In the case of PDT, the chemical liquid holding part 42 of the working side electrode structure 12 holds a photosensitizing substance, and from the irradiated optical fiber 24, it can be absorbed by the photosensitizing substance. Light of a wavelength, for example, ultraviolet rays, is supplied from the laser light source 58 while being controlled by the controller 56, so that the affected part can be irradiated.

In addition, since the light sensitizer is used for PDT, light having a wavelength having a sensitivity is used. In this case, a light source for emitting the light having the wavelength is provided separately, and an input switching means to the optical fiber 24 for irradiation light is shown. Omit), it is assumed that white light or light of the wavelength is selectively switched. Moreover, you may use the filter which transmits only the light of the said wavelength from white light, without using a new light source.

In the present invention, the acting side electrode structure and the non-acting side electrode structure in the catheterized iontophoresis device are provided at the tip of the flexible cable in the endoscope device, for example, an arm in a fire extinguisher. The anticancer agent is infiltrated into the pinpoint of the site by iontophoresis, so there are few side effects and the treatment can be efficiently performed. Immediately after the PDT, the anticancer agent can be administered by exchanging the acting electrode structure and the non-acting electrode structure to simultaneously realize treatment and prevention of recurrence.

Claims (9)

Ion earth having a working side electrode structure and a non-acting electrode structure used for administering the ionic agent by iontophoresis, and a direct current power source connected to these working side electrode structures and the non-acting electrode structure with different polarities. In a foresis device, And a rod-shaped member for supporting the working side electrode structure and the non-acting side electrode structure, and an endoscope apparatus for freely attaching and detaching the rod-shaped member. And a gap of a certain distance is formed between the rod-shaped members, and the rod-shaped members are supported to be bent by a flexible tube in the endoscope apparatus. A catheterized iontophoresis device, wherein the catheter is detachably supported at the tip of the cable. The method of claim 1, The ionic agent is a light sensitizing reaction substance that absorbs and operates light, and the endoscope device has an irradiation optical system that irradiates light from near the distal end of the working side electrode structure by the flexible tube. Catheter type iontophoresis device. The method of claim 2, The endoscope apparatus has an endoscope optical system including an optical fiber for irradiation light for irradiating the inside of the living body and an optical fiber for reflection light for guiding the reflected light to the outside, wherein the irradiation optical system is the catheter for the irradiation light. Type iontophoresis device. The method according to any one of claims 1 to 3, Wiring from the DC power supply is housed in the flexible cable, and has a power supply side working electrode terminal and a power supply side non-operating electrode terminal connected to different polarities of the DC power supply through the wiring. The rod-shaped member has a working electrode side contact and a non-acting electrode side contact connected to or separated from the power supply side working electrode terminal and the power supply side non-operating electrode terminal at the base end on the detachable side to the flexible cable. , These working electrode side contacts and non-working electrode side contacts are connected to the working side electrode and the non-acting side electrode in the working side electrode structure and the non-acting side electrode structure, and the catheterized iontophoresis device characterized by the above-mentioned. . The method of claim 4, wherein The endoscope device is provided with a control device, which is arranged in a power supply circuit between the power supply side working electrode terminal and the power supply side non-operating electrode terminal and the DC power supply, and among the energization time which is the current value and administration time at the time of energization. A catheter type iontophoresis device, characterized in that at least a current value is adjusted. The method according to any one of claims 1 to 5, The catheterized iontophoresis device, wherein the acting electrode structure and the non-acting electrode structure are arranged so that their respective central axes are parallel to each other. The method according to any one of claims 1 to 5, The catheterized iontophoresis device, wherein the working side electrode structure and the non-working side electrode structure are arranged so that their respective central axes extend in the tip direction. The method according to any one of claims 1 to 5, The catheter-type iontophoresis device, wherein the acting side electrode structure and the non-acting side electrode structure are arranged so that their respective central axes cross in the tip direction. The method according to any one of claims 1 to 8, The working side electrode structure includes: the working side electrode connected to the same polarity as that of the charged ion of the ionic drug in the DC power source; An electrolyte holding unit disposed on the front surface of the working side electrode and holding an electrolyte; A second ion exchange membrane disposed on the front surface of the electrolyte holding portion and selecting ions opposite to the charged ions of the ionic agent; A chemical liquid holding part disposed on the front surface of the second ion exchange membrane and holding the ionic drug; It is disposed on the front surface of the chemical liquid holding portion, and consists of a first ion exchange membrane which is the ion exchange membrane for selecting ions of the same type as the ions of the ionic drug, The non-action side electrode structure, The non-acting side electrode connected to a polarity opposite to the charged ion of the ionic drug in the DC power source, A second electrolyte holding portion disposed on the front surface of the non-action side electrode and holding a second electrolyte; A third ion exchange membrane disposed on the front surface of the second electrolyte holding portion and selecting ions of the same kind as the charged ions of the ionic agent; A third electrolyte holding portion disposed on the front surface of the third ion exchange membrane and holding a third electrolyte; And a fourth ion exchange membrane, which is disposed on the front surface of the third electrolyte holding portion and is the ion exchange membrane that selects ions opposite to the charged ions of the ionic drug.

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